1. Dark Matter, Dark Energy, How Come Some People Think We Need It and Others Don’t and the Fate of the Universe

2. Unseen Influences in the Cosmos Our goals for learning What do we mean by dark matter and dark energy?

4. Dark Matter: An undetected form of mass that emits little or no light but whose existence we infer from its gravitational influence Dark Energy: An unknown form of energy that seems to be the source of a repulsive force causing the expansion of the universe to accelerate Unseen Influences

5. “Normal” Matter: ~ 4.4% –Normal Matter inside stars:~ 0.6% –Normal Matter outside stars:~ 3.8% Dark Matter: ~ 25% Dark Energy~ 71% Supposed answer according to most astronomers at the moment, but how come! Contents of Universe Majority View

6. What have we learned? What do we mean by dark matter and dark energy? –“Dark matter” is the name given to the unseen mass whose gravity governs the observed motions of stars and gas clouds –“Dark energy” is the name given to whatever might be causing the expansion of the universe to accelerate

7. Evidence for Dark Matter Our goals for learning What is the evidence for dark matter in galaxies? What is the evidence for dark matter in clusters of galaxies? Does dark matter really exist? What might dark matter be made of?

8. What is the evidence for dark matter in galaxies?

9. Mass within Sun’s orbit: 1.0 x 10 11 M Sun Total mass: ~10 12 M Sun

10. The visible portion of a galaxy lies deep in the heart of a large halo of dark matter

11. We can measure rotation curves of other spiral galaxies using the Doppler shift of the 21-cm line of atomic H

12. Spiral galaxies all tend to have flat rotation curves indicating large amounts of dark matter

13. Broadening of spectral lines in elliptical galaxies tells us how fast the stars are orbiting These galaxies also have dark matter

14. Thought Question What would you conclude about a galaxy whose rotational velocity rises steadily with distance beyond the visible part of its disk? A. Its mass is concentrated at the center B. It rotates like the solar system C. It’s especially rich in dark matter D. It’s just like the Milky Way

15. Thought Question What would you conclude about a galaxy whose rotational velocity rises steadily with distance beyond the visible part of its disk? A. Its mass is concentrated at the center B. It rotates like the solar system C. It’s especially rich in dark matter D. It’s just like the Milky Way

16. What is the evidence for dark matter in clusters of galaxies?

17. We can measure the velocities of galaxies in a cluster from their Doppler shifts

18. The mass we find from galaxy motions in a cluster is about 50 times larger than the mass in stars!

19. Clusters contain large amounts of X- ray emitting hot gas Temperature of hot gas (particle motions) tells us cluster mass: 85% dark matter 13% hot gas 2% stars

20. Gravitational lensing, the bending of light rays by gravity, can also tell us a cluster’s mass

22. All three methods of measuring cluster mass indicate similar amounts of dark matter, maybe not similar!

23. Thought Question What kind of measurement does not tell us the mass of a cluster of galaxies? A. Measure velocities of cluster galaxies B. Measure total mass of cluster’s stars C. Measure temperature of its hot gas D. Measure distorted images of background galaxies

24. Thought Question What kind of measurement does not tell us the mass of a cluster of galaxies? A. Measure velocities of cluster galaxies B. Measure total mass of cluster’s stars C. Measure temperature of its hot gas D. Measure distorted images of background galaxies

25. Does dark matter really exist?

26. Our Options 1.Dark matter really exists, and we are observing the effects of its gravitational attraction 2.Something is wrong with our understanding of gravity or other physics, causing us to mistakenly infer the existence of dark matter

27. Majority Option 1.Dark matter really exists, and we are observing the effects of its gravitational attraction 2.Something is wrong with our understanding of gravity or other physics, causing us to mistakenly infer the existence of dark matter Because gravity is so well tested, most astronomers prefer option #1 Dr. Harold Williams prefered MOND, now Cosmological Realtivity by Moshe Carmeli!

28. What might dark matter be made of?

29. How dark is it?

30. … not as bright as a star. How dark is it?

31. Ordinary Dark Matter (MACHOS) –Massive Compact Halo Objects: dead or failed stars in halos of galaxies Extraordinary Dark Matter (WIMPS) –Weakly Interacting Massive Particles: mysterious neutrino-like particles Two Basic Options

32. Ordinary Dark Matter (MACHOS) –Massive Compact Halo Objects: dead or failed stars in halos of galaxies Extraordinary Dark Matter (WIMPS) –Weakly Interacting Massive Particles: mysterious neutrino-like particles Two Basic Options The Best Bet

33. MACHOs occasionally make other stars appear brighter through lensing

34. … but not enough lensing events to explain all the dark matter

35. There’s not enough ordinary matter WIMPs could be left over from Big Bang Models involving WIMPs explain how galaxy formation works Why Majority Believe in WIMPs?

36. What have we learned? What is the evidence for dark matter in galaxies? –Rotation curves of galaxies are flat, indicating that most of their matter lies outside their visible regions What is the evidence for dark matter in clusters of galaxies? –Masses measured from galaxy motions, temperature of hot gas, and gravitational lensing all indicate that the vast majority of matter in clusters is dark

37. What have we learned? Does dark matter really exist? –Either dark matter exists or our understanding of our gravity must be revised What might dark matter be made of? –There does not seem to be enough normal (baryonic) matter to account for all the dark matter, so most astronomers suspect that dark matter is made of (non-baryonic) particles that have not yet been discovered

38. Structure Formation Our goals for learning What is the role of dark matter in galaxy formation? What are the largest structures in the universe?

39. What is the role of dark matter in galaxy formation?

40. Gravity of dark matter is what caused protogalactic clouds to contract early in time 

41. WIMPs can’t contract to center because they don’t radiate away their orbital energy

42. Dark matter is still pulling things together After correcting for Hubble’s Law, we can see that galaxies are flowing toward the densest regions of space

43. What are the largest structures in the universe?

44. Maps of galaxy positions reveal extremely large structures: superclusters and voids

45. Models show that gravity of dark matter pulls mass into denser regions – universe grows lumpier with time Time in billions of years 0.5 2.25.98.613.7 Size of expanding box in millions of lt-yrs 13 357093140

46. Models show that gravity of dark matter pulls mass into denser regions – universe grows lumpier with time

47. Structures in galaxy maps look very similar to the ones found in models in which dark matter is WIMPs

48. What have we learned? What is the role of dark matter in galaxy formation? –The gravity of dark matter seems to be what drew gas together into protogalactic clouds, initiating the process of galaxy formation What are the largest structures in the universe? –Galaxies appear to be distributed in gigantic chains and sheets that surround great voids

49. The Fate of the Universe Our goals for learning Will the universe continue expanding forever? Is the expansion of the universe accelerating?

50. Will the universe continue expanding forever?

51. Critical density of matter Not enough dark matter Fate of universe depends on the amount of dark matter Lots of dark matter

52. Amount of dark matter is ~25% of the critical density suggesting fate is eternal expansion Not enough dark matter

53. But expansion appears to be speeding up! Not enough dark matter Dark Energy?

54. Estimated age depends on both dark matter and dark energy old older oldest

55. Thought Question Suppose that the universe has more dark matter than we think there is today – how would that change the age we estimate from the expansion rate ? A. Estimated age would be larger B. Estimated age would be the same C. Estimated age would be smaller

56. Thought Question Suppose that the universe has more dark matter than we think there is today – how would that change the age we estimate from the expansion rate ? A. Estimated age would be larger B. Estimated age would be the same C. Estimated age would be smaller

57. Is the expansion of the universe accelerating?

58. Brightness of distant white-dwarf supernovae tells us how much universe has expanded since they exploded

59. Accelerating universe is best fit to supernova data

60. What have we learned? Will the universe continue expanding forever? –Current measurements indicate that there is not enough dark matter to prevent the universe from expanding forever Is the expansion of the universe accelerating? –An accelerating universe is the best explanation for the distances we measure when using white dwarf supernovae as standard candles